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utilities.py
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utilities.py
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import datetime
import numpy as np
import scipy.sparse as sp
import pyscipopt as scip
import pickle
import gzip
def log(str, logfile=None):
str = f'[{datetime.datetime.now()}] {str}'
print(str)
if logfile is not None:
with open(logfile, mode='a') as f:
print(str, file=f)
def init_scip_params(model, seed, heuristics=True, presolving=True, separating=True, conflict=True):
seed = seed % 2147483648 # SCIP seed range
# set up randomization
model.setBoolParam('randomization/permutevars', True)
model.setIntParam('randomization/permutationseed', seed)
model.setIntParam('randomization/randomseedshift', seed)
# separation only at root node
model.setIntParam('separating/maxrounds', 0)
# no restart
model.setIntParam('presolving/maxrestarts', 0)
# if asked, disable presolving
if not presolving:
model.setIntParam('presolving/maxrounds', 0)
model.setIntParam('presolving/maxrestarts', 0)
# if asked, disable separating (cuts)
if not separating:
model.setIntParam('separating/maxroundsroot', 0)
# if asked, disable conflict analysis (more cuts)
if not conflict:
model.setBoolParam('conflict/enable', False)
# if asked, disable primal heuristics
if not heuristics:
model.setHeuristics(scip.SCIP_PARAMSETTING.OFF)
def extract_state(model, buffer=None):
"""
Compute a bipartite graph representation of the solver. In this
representation, the variables and constraints of the MILP are the
left- and right-hand side nodes, and an edge links two nodes iff the
variable is involved in the constraint. Both the nodes and edges carry
features.
Parameters
----------
model : pyscipopt.scip.Model
The current model.
buffer : dict
A buffer to avoid re-extracting redundant information from the solver
each time.
Returns
-------
variable_features : dictionary of type {'names': list, 'values': np.ndarray}
The features associated with the variable nodes in the bipartite graph.
edge_features : dictionary of type ('names': list, 'indices': np.ndarray, 'values': np.ndarray}
The features associated with the edges in the bipartite graph.
This is given as a sparse matrix in COO format.
constraint_features : dictionary of type {'names': list, 'values': np.ndarray}
The features associated with the constraint nodes in the bipartite graph.
"""
if buffer is None or model.getNNodes() == 1:
buffer = {}
# update state from buffer if any
s = model.getState(buffer['scip_state'] if 'scip_state' in buffer else None)
buffer['scip_state'] = s
if 'state' in buffer:
obj_norm = buffer['state']['obj_norm']
else:
obj_norm = np.linalg.norm(s['col']['coefs'])
obj_norm = 1 if obj_norm <= 0 else obj_norm
row_norms = s['row']['norms']
row_norms[row_norms == 0] = 1
# Column features
n_cols = len(s['col']['types'])
if 'state' in buffer:
col_feats = buffer['state']['col_feats']
else:
col_feats = {}
col_feats['type'] = np.zeros((n_cols, 4)) # BINARY INTEGER IMPLINT CONTINUOUS
col_feats['type'][np.arange(n_cols), s['col']['types']] = 1
col_feats['coef_normalized'] = s['col']['coefs'].reshape(-1, 1) / obj_norm
col_feats['has_lb'] = ~np.isnan(s['col']['lbs']).reshape(-1, 1)
col_feats['has_ub'] = ~np.isnan(s['col']['ubs']).reshape(-1, 1)
col_feats['sol_is_at_lb'] = s['col']['sol_is_at_lb'].reshape(-1, 1)
col_feats['sol_is_at_ub'] = s['col']['sol_is_at_ub'].reshape(-1, 1)
col_feats['sol_frac'] = s['col']['solfracs'].reshape(-1, 1)
col_feats['sol_frac'][s['col']['types'] == 3] = 0 # continuous have no fractionality
col_feats['basis_status'] = np.zeros((n_cols, 4)) # LOWER BASIC UPPER ZERO
col_feats['basis_status'][np.arange(n_cols), s['col']['basestats']] = 1
col_feats['reduced_cost'] = s['col']['redcosts'].reshape(-1, 1) / obj_norm
col_feats['age'] = s['col']['ages'].reshape(-1, 1) / (s['stats']['nlps'] + 5)
col_feats['sol_val'] = s['col']['solvals'].reshape(-1, 1)
col_feats['inc_val'] = s['col']['incvals'].reshape(-1, 1)
col_feats['avg_inc_val'] = s['col']['avgincvals'].reshape(-1, 1)
col_feat_names = [[k, ] if v.shape[1] == 1 else [f'{k}_{i}' for i in range(v.shape[1])] for k, v in col_feats.items()]
col_feat_names = [n for names in col_feat_names for n in names]
col_feat_vals = np.concatenate(list(col_feats.values()), axis=-1)
variable_features = {
'names': col_feat_names,
'values': col_feat_vals,}
# Row features
if 'state' in buffer:
row_feats = buffer['state']['row_feats']
has_lhs = buffer['state']['has_lhs']
has_rhs = buffer['state']['has_rhs']
else:
row_feats = {}
has_lhs = np.nonzero(~np.isnan(s['row']['lhss']))[0]
has_rhs = np.nonzero(~np.isnan(s['row']['rhss']))[0]
row_feats['obj_cosine_similarity'] = np.concatenate((
-s['row']['objcossims'][has_lhs],
+s['row']['objcossims'][has_rhs])).reshape(-1, 1)
row_feats['bias'] = np.concatenate((
-(s['row']['lhss'] / row_norms)[has_lhs],
+(s['row']['rhss'] / row_norms)[has_rhs])).reshape(-1, 1)
row_feats['is_tight'] = np.concatenate((
s['row']['is_at_lhs'][has_lhs],
s['row']['is_at_rhs'][has_rhs])).reshape(-1, 1)
row_feats['age'] = np.concatenate((
s['row']['ages'][has_lhs],
s['row']['ages'][has_rhs])).reshape(-1, 1) / (s['stats']['nlps'] + 5)
# # redundant with is_tight
# tmp = s['row']['basestats'] # LOWER BASIC UPPER ZERO
# tmp[s['row']['lhss'] == s['row']['rhss']] = 4 # LOWER == UPPER for equality constraints
# tmp_l = tmp[has_lhs]
# tmp_l[tmp_l == 2] = 1 # LHS UPPER -> BASIC
# tmp_l[tmp_l == 4] = 2 # EQU UPPER -> UPPER
# tmp_l[tmp_l == 0] = 2 # LHS LOWER -> UPPER
# tmp_r = tmp[has_rhs]
# tmp_r[tmp_r == 0] = 1 # RHS LOWER -> BASIC
# tmp_r[tmp_r == 4] = 2 # EQU LOWER -> UPPER
# tmp = np.concatenate((tmp_l, tmp_r)) - 1 # BASIC UPPER ZERO
# row_feats['basis_status'] = np.zeros((len(has_lhs) + len(has_rhs), 3))
# row_feats['basis_status'][np.arange(len(has_lhs) + len(has_rhs)), tmp] = 1
tmp = s['row']['dualsols'] / (row_norms * obj_norm)
row_feats['dualsol_val_normalized'] = np.concatenate((
-tmp[has_lhs],
+tmp[has_rhs])).reshape(-1, 1)
row_feat_names = [[k, ] if v.shape[1] == 1 else [f'{k}_{i}' for i in range(v.shape[1])] for k, v in row_feats.items()]
row_feat_names = [n for names in row_feat_names for n in names]
row_feat_vals = np.concatenate(list(row_feats.values()), axis=-1)
constraint_features = {
'names': row_feat_names,
'values': row_feat_vals,}
# Edge features
if 'state' in buffer:
edge_row_idxs = buffer['state']['edge_row_idxs']
edge_col_idxs = buffer['state']['edge_col_idxs']
edge_feats = buffer['state']['edge_feats']
else:
coef_matrix = sp.csr_matrix(
(s['nzrcoef']['vals'] / row_norms[s['nzrcoef']['rowidxs']],
(s['nzrcoef']['rowidxs'], s['nzrcoef']['colidxs'])),
shape=(len(s['row']['nnzrs']), len(s['col']['types'])))
coef_matrix = sp.vstack((
-coef_matrix[has_lhs, :],
coef_matrix[has_rhs, :])).tocoo(copy=False)
edge_row_idxs, edge_col_idxs = coef_matrix.row, coef_matrix.col
edge_feats = {}
edge_feats['coef_normalized'] = coef_matrix.data.reshape(-1, 1)
edge_feat_names = [[k, ] if v.shape[1] == 1 else [f'{k}_{i}' for i in range(v.shape[1])] for k, v in edge_feats.items()]
edge_feat_names = [n for names in edge_feat_names for n in names]
edge_feat_indices = np.vstack([edge_row_idxs, edge_col_idxs])
edge_feat_vals = np.concatenate(list(edge_feats.values()), axis=-1)
edge_features = {
'names': edge_feat_names,
'indices': edge_feat_indices,
'values': edge_feat_vals,}
if 'state' not in buffer:
buffer['state'] = {
'obj_norm': obj_norm,
'col_feats': col_feats,
'row_feats': row_feats,
'has_lhs': has_lhs,
'has_rhs': has_rhs,
'edge_row_idxs': edge_row_idxs,
'edge_col_idxs': edge_col_idxs,
'edge_feats': edge_feats,
}
return constraint_features, edge_features, variable_features
def valid_seed(seed):
"""Check whether seed is a valid random seed or not."""
seed = int(seed)
if seed < 0 or seed > 2**32 - 1:
raise argparse.ArgumentTypeError(
"seed must be any integer between 0 and 2**32 - 1 inclusive")
return seed
def compute_extended_variable_features(state, candidates):
"""
Utility to extract variable features only from a bipartite state representation.
Parameters
----------
state : dict
A bipartite state representation.
candidates: list of ints
List of candidate variables for which to compute features (given as indexes).
Returns
-------
variable_states : np.array
The resulting variable states.
"""
constraint_features, edge_features, variable_features = state
constraint_features = constraint_features['values']
edge_indices = edge_features['indices']
edge_features = edge_features['values']
variable_features = variable_features['values']
cand_states = np.zeros((
len(candidates),
variable_features.shape[1] + 3*(edge_features.shape[1] + constraint_features.shape[1]),
))
# re-order edges according to variable index
edge_ordering = edge_indices[1].argsort()
edge_indices = edge_indices[:, edge_ordering]
edge_features = edge_features[edge_ordering]
# gather (ordered) neighbourhood features
nbr_feats = np.concatenate([
edge_features,
constraint_features[edge_indices[0]]
], axis=1)
# split neighborhood features by variable, along with the corresponding variable
var_cuts = np.diff(edge_indices[1]).nonzero()[0]+1
nbr_feats = np.split(nbr_feats, var_cuts)
nbr_vars = np.split(edge_indices[1], var_cuts)
assert all([all(vs[0] == vs) for vs in nbr_vars])
nbr_vars = [vs[0] for vs in nbr_vars]
# process candidate variable neighborhoods only
for var, nbr_id, cand_id in zip(*np.intersect1d(nbr_vars, candidates, return_indices=True)):
cand_states[cand_id, :] = np.concatenate([
variable_features[var, :],
nbr_feats[nbr_id].min(axis=0),
nbr_feats[nbr_id].mean(axis=0),
nbr_feats[nbr_id].max(axis=0)])
cand_states[np.isnan(cand_states)] = 0
return cand_states
def extract_khalil_variable_features(model, candidates, root_buffer):
"""
Extract features following Khalil et al. (2016) Learning to Branch in Mixed Integer Programming.
Parameters
----------
model : pyscipopt.scip.Model
The current model.
candidates : list of pyscipopt.scip.Variable's
A list of variables for which to compute the variable features.
root_buffer : dict
A buffer to avoid re-extracting redundant root node information (None to deactivate buffering).
Returns
-------
variable_features : 2D np.ndarray
The features associated with the candidate variables.
"""
# update state from state_buffer if any
scip_state = model.getKhalilState(root_buffer, candidates)
variable_feature_names = sorted(scip_state)
variable_features = np.stack([scip_state[feature_name] for feature_name in variable_feature_names], axis=1)
return variable_features
def preprocess_variable_features(features, interaction_augmentation, normalization):
"""
Features preprocessing following Khalil et al. (2016) Learning to Branch in Mixed Integer Programming.
Parameters
----------
features : 2D np.ndarray
The candidate variable features to preprocess.
interaction_augmentation : bool
Whether to augment features with 2-degree interactions (useful for linear models such as SVMs).
normalization : bool
Wether to normalize features in [0, 1] (i.e., query-based normalization).
Returns
-------
variable_features : 2D np.ndarray
The preprocessed variable features.
"""
# 2-degree polynomial feature augmentation
if interaction_augmentation:
interactions = (
np.expand_dims(features, axis=-1) * \
np.expand_dims(features, axis=-2)
).reshape((features.shape[0], -1))
features = np.concatenate([features, interactions], axis=1)
# query-based normalization in [0, 1]
if normalization:
features -= features.min(axis=0, keepdims=True)
max_val = features.max(axis=0, keepdims=True)
max_val[max_val == 0] = 1
features /= max_val
return features
def load_flat_samples(filename, feat_type, label_type, augment_feats, normalize_feats):
with gzip.open(filename, 'rb') as file:
sample = pickle.load(file)
state, khalil_state, best_cand, cands, cand_scores = sample['data']
cands = np.array(cands)
cand_scores = np.array(cand_scores)
cand_states = []
if feat_type in ('all', 'gcnn_agg'):
cand_states.append(compute_extended_variable_features(state, cands))
if feat_type in ('all', 'khalil'):
cand_states.append(khalil_state)
cand_states = np.concatenate(cand_states, axis=1)
best_cand_idx = np.where(cands == best_cand)[0][0]
# feature preprocessing
cand_states = preprocess_variable_features(cand_states, interaction_augmentation=augment_feats, normalization=normalize_feats)
if label_type == 'scores':
cand_labels = cand_scores
elif label_type == 'ranks':
cand_labels = np.empty(len(cand_scores), dtype=int)
cand_labels[cand_scores.argsort()] = np.arange(len(cand_scores))
elif label_type == 'bipartite_ranks':
# scores quantile discretization as in
# Khalil et al. (2016) Learning to Branch in Mixed Integer Programming
cand_labels = np.empty(len(cand_scores), dtype=int)
cand_labels[cand_scores >= 0.8 * cand_scores.max()] = 1
cand_labels[cand_scores < 0.8 * cand_scores.max()] = 0
else:
raise ValueError(f"Invalid label type: '{label_type}'")
return cand_states, cand_labels, best_cand_idx